JP3368371B2 - Flue gas denitration equipment - Google Patents

Description

Detailed Description of the Invention

[0001]

TECHNICAL FIELD The present invention relates to a refuse incineration facility,
Exhaust gas that removes a large amount of nitrogen oxides (NOx) contained in the exhaust gas emitted from fixed sources such as various boiler facilities
Denitration equipment

[0002]

2. Description of the Related Art As a conventional flue gas denitration method, urea is directly blown into a furnace such as a refuse incineration facility or various boiler facilities.
A non-catalytic denitration method in which this is decomposed by heat to generate ammonia, and this ammonia is used as a reducing agent,
A catalytic denitration method in which ammonia is used as a reducing agent and nitrogen oxides are reduced in the presence of a catalyst is known.

[0003]

In the conventional non-catalytic denitration method, urea is decomposed by heat to generate ammonia, and this ammonia is used as a reducing agent. However, since the decomposition efficiency of urea is poor, NOx On the other hand, there is a problem in that a large amount of urea, which is equal to or more than the equimolar amount, is required, resulting in an increase in cost and a large amount of ammonia leaking to generate white smoke from the chimney. Moreover, the denitration efficiency is poor.

Further, in the conventional catalytic denitration method, it is necessary to transport and store a large amount of ammonia gas having strong toxicity and strong odor. Therefore, if this should happen, there is a great danger, and there are many legal restrictions.

The object of the present invention is to solve the above problems, to eliminate nitrogen oxides efficiently without using a large amount of urea, and to carry out mass transportation and storage of ammonia which is subject to many legal restrictions. It is to provide a flue gas denitration device that does not require.

[0006]

According to a first aspect of the present invention, there is provided a flue gas denitration device for reducing and removing nitrogen oxides in flue gas emitted from a fixed generation source, the fixed generation source and a denitration device. Is connected by a pipe, an ammonia supply pipe extending from a urea decomposer having a urea decomposition catalyst is connected to the pipe, and the urea decomposer is a urea decomposition catalyst.
Two or more urea decomposition chambers each having a urea decomposition chamber
Means for supplying urea water into the chamber and each urea decomposition chamber
Ammonia generated by the decomposition of urea in the denitration unit
Means for supplying carrier gas for transportation and each urea decomposition chamber
And a means for heating the inside of the bath,
Switch to one of the urea decomposition chambers by the supply means
While being supplied, the carrier gas is supplied to the carrier gas supply means.
Is supplied by switching to one of the urea decomposition chambers.
It is done like this. According to the flue gas denitrification apparatus of the invention of claim 1, the ammonia decomposed and produced from urea in the urea decomposer in the presence of a catalyst passes through the ammonia supply pipe and the pipe together with the flue gas containing nitrogen oxides, and the denitrifier Sent to. Therefore, there is no need for mass transportation and storage of ammonia, which is often legally regulated. Further, since urea is decomposed in the presence of a catalyst to generate ammonia, the decomposition efficiency of urea is improved and the production rate of ammonia is improved. Further, if the urea water and the carrier gas are supplied to the same urea decomposition chamber, the ammonia decomposed and produced in the presence of the catalyst is sent to the denitration unit by the carrier gas.
Then, after a lapse of a predetermined time, the supply destinations of the urea water and the carrier gas are switched to another urea decomposition chamber. At this time,
Since the urea decomposition catalyst in the other urea decomposition chamber is kept in a dry state, urea is always decomposed using the dried catalyst, and the decomposition efficiency of urea is improved. If the catalyst remains wet, the temperature will drop and the decomposition efficiency will decrease.
Further, while the urea is being decomposed in one urea decomposition chamber, the catalysts in the other urea decomposition chambers can be replaced at the same time, and it is not necessary to stop the denitration work.

The flue gas denitration device according to the invention of claim 2 is
Reduction and removal of nitrogen oxides in flue gas emitted from constant sources
It is a device that uses a pipe to connect the fixed source and the denitration device.
Connected and extended from a urea decomposer with a urea decomposition catalyst
The ammonia supply pipe is connected to the pipe, and the urea decomposer has one urea decomposition chamber having a urea decomposition catalyst, a means for supplying urea water into the urea decomposition chamber, and a urea decomposition chamber. It is equipped with a means for supplying a carrier gas that conveys the ammonia generated by the decomposition of urea to the denitration unit and a means for heating the inside of the urea decomposition chamber, and the urea decomposition catalyst is cylindrical and has its axis centered. adapted to rotate, also urea water supply means are adapted to spray urea water into a portion of the urea cracking catalyst
Of. According to the flue gas denitration device of the invention of claim 2, urine
The decomposition product of urea from urea in the presence of a catalyst in an elementary decomposer.
Monia passes through the ammonia supply pipes and pipes
It is sent to the denitration equipment together with the exhaust gas containing the oxides. But
Therefore, mass transportation and storage of ammonia, which is subject to many legal regulations,
do not need. In addition, urea is decomposed in the presence of a catalyst to
As it produces ammonia, it improves the decomposition efficiency of urea.
However, the production rate of ammonia is improved. Further, when urea water is sprayed onto a part of the urea decomposition catalyst and the carrier gas is supplied to the urea decomposition chamber, the ammonia decomposed and produced in the presence of the catalyst is sent to the denitration unit by the carrier gas. The urea decomposition catalyst is cylindrical and is configured to rotate about its axis, and the urea water supply means is
Since the urea water is sprayed onto a part of the urea decomposition catalyst, the part of the catalyst sprayed with the urea water is dried while returning to the spray part of the urea water again. Therefore, urea can be decomposed using a dry catalyst at all times, so that the decomposition efficiency of urea is improved. If the catalyst remains wet, the temperature will drop and the decomposition efficiency will decrease.

In the above two flue gas denitration devices, the carrier gas used is, for example, the atmosphere or an inert gas such as nitrogen gas.

In the above two flue gas denitration devices, the urea decomposition catalyst is preferably one in which tungsten or molybdenum or a mixture thereof is supported on a porous carrier.

[0010]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described below.
A description will be given with reference to the drawings.

As shown in FIG. 1, the flue gas denitration apparatus comprises a furnace (1) such as refuse incineration equipment and various boiler equipment, and a denitration tower (3) connected to the furnace (1) through a pipe (2). ) (Denitrifier). A dust collector (4) is provided in the middle of the pipe (2).
An ammonia supply pipe (6) extending from a urea decomposer (5) having a urea decomposition catalyst is connected to a portion of the pipe (2) between the dust collector (4) and the denitration tower (3). A chimney (7) is connected to the downstream side of the denitration tower (3).

In the denitration tower (3), for example, a denitration catalyst (not shown) in which molybdenum is supported on a titania carrier is arranged.

As shown in FIG. 2, the urea decomposer (5) has two or more, for example, two, each having a urea decomposition catalyst (8).
One urea decomposition chamber (9), means for supplying urea water into each urea decomposition chamber (9), and denitration tower (3) for ammonia generated by decomposition of urea in each urea decomposition chamber (9)
And a heater (10) (heating means) for heating the inside of each urea decomposition chamber (9).

The urea decomposition catalyst (8) is a porous carrier on which tungsten or molybdenum or a mixture thereof is supported.

The urea water supply means has a urea water tank (11), and one end of a urea water supply pipe (12) is connected to the urea water tank (11). The other end of the urea water supply pipe (12) is connected to the same number of branch pipes (14) as there are urea decomposition chambers (9) via a switching valve (13), and each branch pipe (14) is It is connected to the urea decomposition chamber (9). A nozzle (15) for spraying urea water is attached to the tip of each branch pipe (14). The urea water in the urea water tank (11) is sent by the pump (16) through the urea water supply pipe (12) to one of the branch pipes (14), and the nozzle (15) at the tip of the urea water tank It is adapted to be sprayed into the urea decomposition chamber (9).

The carrier gas supply means comprises a carrier gas supply pipe (17) having one end connected to a carrier gas source (not shown) and the other end connected to each urea decomposition chamber (9). . Then, the carrier gas is switched and supplied to one of the urea decomposition chambers (9) by the carrier gas supply means.

Each urea decomposition chamber (9) has a gas outlet pipe (1
8) is connected, and the tip of each gas outlet pipe (18) is connected to the ammonia supply pipe (6).

The flue gas denitration method using the above flue gas denitration apparatus is as follows. First, the flue gas containing nitrogen oxides is sent to the denitration tower (3) via the dust collector (4). Then, inside each urea decomposition chamber (9) of the urea decomposition unit (5), an electric heater
According to (10), it is heated and maintained at 200 to 400 ° C. At the same time, the urea water supply means sprays urea water into one of the urea decomposition chambers (9), and the carrier gas supply means sprays urea water into the same urea decomposition chamber (9). Supply carrier gas. Then the catalyst
Urea decomposes in the presence of (8) to produce ammonia.
This ammonia is carried by the carrier gas blown out into the same urea decomposition chamber (9), and passes through the ammonia supply pipe (6) from the gas outlet pipe (18) to the dust collector in the pipe (2).
It is sent to the part between (4) and the denitration tower (3), and enters the denitration tower (3) together with the exhaust gas. Then, in the denitration tower (3), nitrogen oxides are removed using ammonia as a reducing agent in the presence of a catalyst. After the lapse of a predetermined time, the supply valve for urea water and carrier gas is switched to another urea decomposition chamber by the switching valve (13).
Switch to (9). At this time, since the urea decomposition catalyst (8) in the other urea decomposition chamber (9) is kept in a dry state,
Urea can be decomposed using an always dry catalyst,
The decomposition efficiency of urea is improved.

FIG. 3 shows a modification of the urea decomposer.

In FIG. 3, the urea decomposer (20) comprises a urea decomposition chamber (22) containing a urea decomposition catalyst (21).
Is equipped with. A means for supplying urea water into the urea decomposition chamber (22), a means for supplying a carrier gas for conveying the ammonia generated by the decomposition of urea to the denitration tower (3) in the urea decomposition chamber (22), and a urea decomposition An electric heater (10) (heating means) for heating the inside of the chamber (22) is provided. An ammonia supply pipe (6) is connected to the urea decomposition chamber (22).

The urea water supply means includes a urea water tank (not shown) and a urea water supply pipe (23) having one end connected to the urea water tank and the other end connected to the urea decomposition chamber (22).
And a nozzle (24) for spraying urea water, which is attached to an end of the urea water supply pipe (23) on the urea decomposition chamber (22) side. The urea water in the urea water tank is sprayed into the urea decomposition chamber (22) from a nozzle (24) at the tip of the urea water supply pipe (23) by a pump (not shown).

The carrier gas supply means comprises a carrier gas supply pipe (25) having one end connected to a carrier gas source (not shown) and the other end connected to the urea decomposition chamber (22).

The urea decomposition catalyst (21) is a porous carrier in which tungsten, molybdenum, or a mixture thereof is supported, and is formed in a laterally cylindrical shape. A rotary shaft (27) is attached to the axial center of the catalyst (21) via a connecting member (28), and the rotary shaft (27) is rotatably supported by the peripheral wall of the urea decomposition chamber (22). Along with
It can be rotated by a suitable known means (not shown). The urea water supply means is a urea decomposition catalyst (21)
Urea water is sprayed on the upper part of the.

In the case of this urea decomposer (20), the urea decomposer (2
The inside of the urea decomposition chamber (22) of (0) is heated and maintained at 200 to 400 ° C. by the electric heater (10), and while the catalyst (21) is rotated at a predetermined rotation speed, the urea water is decomposed into the urea decomposition chamber (22). 2
It sprays toward the upper part of the catalyst (21) in 2) and decomposes urea in the presence of the catalyst (21) to produce ammonia. Catalyst (21)
Since is rotated, the sprayed portion of the urea water in the catalyst (21) is dried while returning to the spray portion of the urea water again. Therefore, urea can be decomposed using a dry catalyst at all times, and the efficiency of urea decomposition is improved .
It

[0025]

Effects of the Invention According to the flue gas denitration apparatus according to claim 1 and 2 of the present invention, as described above, by decomposing urea on site i.e. situ to produce ammonia, because use of ammonia as a reducing agent The safety is improved without the need for mass transportation and storage of ammonia, which is often legally regulated.
Further, since urea is decomposed in the presence of a catalyst to generate ammonia, the decomposition efficiency of urea is improved, the production rate of ammonia is improved, and as a result, the denitration efficiency is improved and the amount of urea used is increased. The cost is reduced by reducing.

[Brief description of drawings]

FIG. 1 is a schematic view showing an embodiment of a flue gas denitration device of the present invention.

FIG. 2 is a diagram showing a configuration of a urea decomposer of the apparatus shown in FIG.

FIG. 3 is a diagram showing a configuration of a modified example of a urea decomposer .

[Explanation of symbols]

(1) Furnace (fixed source) (2) Piping (3) Denitration tower (denitizer) (5) (20) Urea decomposer (6) Ammonia supply pipe (8) (21) Urea decomposition catalyst (9) (22) Urea decomposition chamber (10) Electric heater (heating means)

─────────────────────────────────────────────────── ─── Continuation of the front page (56) Reference JP-A-2-191528 (JP, A) JP-A-5-15739 (JP, A) JP-A-6-319950 (JP, A) (58) Field (Int.Cl. ⁷ , DB name) B01D 53/34

Claims (3)

(57) [Claims] 1. Nitrogen in flue gas emitted from a fixed source.
A device for reducing and removing oxides, which has a fixed source and denitration
Urine that is connected to the vessel by a pipe and has a urea decomposition catalyst
The ammonia supply pipe extending from the elementary decomposer is connected to the above pipe.
Urea decomposers are used as catalysts for urea decomposition.
Two or more urea decomposition chambers each having a urea decomposition chamber
Means for supplying urea water into the chamber and each urea decomposition chamber
Ammonia generated by the decomposition of urea in the denitration unit
Means for supplying carrier gas for transportation and each urea decomposition chamber
And a means for heating the inside of the bath,
Switch to one of the urea decomposition chambers by the supply means
While being supplied, the carrier gas is supplied to the carrier gas supply means.
Is supplied by switching to one of the urea decomposition chambers.
Flue gas denitration equipment that is made like. 2. Nitrogen in flue gas emitted from a fixed source.
A device for reducing and removing oxides, which has a fixed source and denitration
Urine that is connected to the vessel by a pipe and has a urea decomposition catalyst
The ammonia supply pipe extending from the elementary decomposer is connected to the above pipe.
And the urea decomposer has a urea decomposition catalyst.
One urea decomposition chamber and urea in the urea decomposition chamber
The amount of urea contained in the means for supplying water and in the urea decomposition chamber
A carrier gas that conveys the ammonia generated by the solution to the denitration unit.
And a means for heating the inside of the urea decomposition chamber.
And the catalyst for urea decomposition is cylindrical and
It is designed to rotate around the axis, and the urea water supply
So that the stage sprays urea water on a part of the urea decomposition catalyst.
Exhaust gas denitration equipment is used. 3. A urea decomposition catalyst is deposited on a porous carrier.
Gustene or molybdenum, or mixtures thereof
The flue gas desorber according to claim 1 or 2, wherein
Glass equipment.